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THE EVOLUTION OF THE RAAHE-LADOGA ZONE IN FINLAND: ISOTOPIC CONSTRAINTS
by
MATTI V AASJOKI and MATTI SAKKO
Vaasjoki, M. & Sakko, M., 1988. The evolution of the Raahe-Ladoga zone in Finland: isotopic constraints. Geological Survey 01 Finland, Bulletin 343, 7-32. 7 figures, 7 tables and two appendices.
The NW-SE trending Raahe-Ladoga zone in the Fennoscandian (Baltic) Shield forms a major ore-bearing district along the Archaean-Proterozoic boundary. New V-Pb mineral analyses on 17 sampies and a review of pre-existing data indicate that:
(I) volumetrically minor but spatially wide1y distributed granitoid rocks in the central part of the belt register V-Pb ages between about 1930 and 1910 Ma ago;
(2) between 1910 and 1900 Ma ago the zone underwent intermediate-acidic voIcanism associated with base metal mineralization;
(3) nickel-bearing early orogenic gabbros were emplaced between 1900 and 1880 Ma ago;
(4) intrusion of syntectonic granitoids, hypersthene granites and plagioclase porphyrites/ ophitic gabbros all along the belt was accompanied by the peak of regional metamorphism in the central and northwestern parts between 1890 and 1875 Ma ago;
(5) posttectonic rocks were emplaced in the central and northwestern parts between 1880 and 1850 Ma ago;
(6) regional metamorphism peaked and migmatization occurred in the southeastern part of the belt between 1830 and 1810 Ma ago;
(7) posttectonic rocks in the southeastern part were emplaced about 1800 Ma ago.
These results together with previous isotope data from Finland suggest that the new Svecofennian crust was rapidly generated between 1930 and 1850 Ma ago by the collision of a Proterozoic oceanic plate with an Archaean continent. Sub sequent underplating in a W-E direction south of 62°N resulted in migmatization at about 1820 Ma and the emplacement of the ca. 1800 Ma post-tectonic granites in southern Finland.
Results on metapelites indicate that whereas zircon tends increasingly to lose its radiogenic lead as the temperature of regional metamorphism rises, total resetting is not achieved, not even at the garnet-cordierite-biotite grade. Only intense migmatization and/ or immediate contact effects of hypersthene granites, approaching temperatures of 800°C, are sufficient to totally reset the V-Pb record of zircons.
Key words: absolute age, V/ Pb, zircon, monazite, igneous rocks, metamorphic rocks, tectonics, Parikkala-Raahe zone, Proterozoic, Vihanti, Pielavesi, Joroinen~ Rantasalmi, Kiuruvesi, Finland
Malli Vaasjoki and Malli Sakko, Geological Survey 01 Finland, 02150 Espoo, Finland
8 Geological Survey of Finland, Bulletin 343
INTRODUCTION
The Raahe-Ladoga zone (see the index map on p. 6) has been recognized as a major tectonic, ore-bearing structure for quite some time (e.g., Kahma, 1973 and 1978). The main geological feature of the zone is the transition from predominantly Archaean rocks in the northeast to a Proterozoie domain in the southwest over a zone a few tens of kilometres wide (Sirnonen et al., 1978) and characterized by a succession of NW -SE trending faults associated with pairs of similarly trending gravimetrie minima and maxima (Elo, pers. comm.). Isotopieally, the zone becomes apparent through the transition of the Nd composition of Svecokarelian granites within the ca. 1900 Ma age group, as the E(Nd) values of the Karelian granitoids indicate a substantial input of Archean crustal material, whereas the Svecofennian granitoids southwest of the zone seem to be derived mainly from a Proterozoie mantle source (Huhma, 1986). The lead isotopic composition of the most prominent base metalore deposits and prospects along the zone appears to be almost constant over a 300 km stretch containing leads relatively low in 207Pb (Vaasjoki, 1981).
Several economic and subeconomic base metal deposits lie within the Raahe-Ladoga zone (Kahma, 1973; Helovuori, 1979; Huhtala, 1979; Mikkola, 1980) and are hosted by metavolcanic and metasedimentary rocks emplaced during the lower Proterozoic Svecokarelian orogeny (Sirnonen, 1971 and 1980). The base metal zone extends from the Gulf of Bothnia to Rautalampi, and at
its northeastern end is surrounded by Sveco· fennian infra- and supracrustal rocks. In its cen· tral part it continues adjacent to the boundaf) of the Archaean craton and the Proterozoic orogenie rocks. Further southeast, it skims tht border of the equally Proterozoie Svecofennian and Karelian rock groups, the latter being penetrated by Archaean gneiss domes forming part of the Presvecokarelian basement (Kouvo, 1958; Kouvo and Tilton, 1966; Wetherill et al., 1962; Gaal, 1980) which led Koistinen (1981) to postulate a northeast dipping suture zone in this area. Superimposed on the base metal district and likewise parallel to the Archaean-Proterozoic boundary, a number of nickel deposits and prospects associated with differentiated mafic intrusions form the Kotalahti Ni-Cu belt (Tontti, 1981).
This report deals with three different parts of the Raahe-Ladoga zone and aims to establish their evolutionary differences with the aid of isotopic determinations. The Vihanti-Pyhäsalmi base metal distriet is of key economie interest and the Pielavesi-Rautalampi area has been previously studied chiefly for its block movements (Marttila, 1976; Korsman et al. 1984). The third geologically different domain is the progressively metamorphosed Joroinen-Sulkava area (Korsman, 1977). In the following pages each of these areas will be treated separately and at the end a synthesis of the tectonic evolution along the Raahe-Ladoga zone will be attempted.
FROM VIHANTI TO PYHÄSALMI: THE DOMAIN OF MAJOR BASE MET AL DEPOSITS
Geological setting and previous isotopic studies
Throughout the Vihanti-Pyhäsalmi area the terrain is flat and outcrops are scarce as most of the area is covered by Pleistocene tills and bogs.
Nevertheless, from previous work (e.g., Wilkman, 1931; Salli, 1964; Gaal et al., 1974; Rauhamäki et al., 1978) and ongoing mapping it
seems that at least two cycles of volcanic activity have occurred in the district. The first one, associated with the base metal ores, was extensively deformed during the Svecokarelian orogeny (Rouhunkoski, 1969; Rauhamäki et al., 1978; Helovuori, 1979; Huhtala, 1979). The lower volcanic sequence is penetrated by early tectonic gabbros and syntectonic granitoids, and there are occasional occurrences of intraformational conglomerates. These in turn are overlain by the younger volcanic sequence, which was terminated by the emplacement of hypabyssal plagioclase porphyrites. At Vihanti, the ore-bearing sequence is cut by fault-controlled diabase dykes . There are also a few apparently post-tectonic granites with unknown contacts in the district.
Most of the rocks within the lower volcanic unit of the Vihanti-Pyhäsalmi area are dacitic in composition and, at Vihanti, are intimately associated with the base metal mineralization consisting of separate pyritic and sphalerite-galena orebodies (Rouhunkoski, 1968; Rauhamäki et al., 1978). At pyhäsalmi, the immediate country rocks of the ore are mica schists of presumed sedimentary origin, but voluminous volcanic rocks occur in that area as weIl. Over the years, many theories have been advanced concerning the genesis of the mineralization, but current opinion favours a volcanic-exhalative origin for the Vihanti deposit in particular (Rauhamäki et al., 1978) and for other ores of the Vihanti-Pyhäsalmi ore zone in general (Helovuori, 1979; Huhtala, 1979). The total reserves of the Vihanti deposit, including mining since 1954, have been estimated at 15.6 Mt of sphalerite-galena ore containing 7rrJo Zn, 0.8rrJo Pb and 0 .5rrJo Cu and 15.9 Mt of pyrite ore mined for its sulphur content (Isokangas, 1979). Corresponding figures for Pyhäsalmi (including mining since 1962) are 31 Mt
Geological Survey of Finland, Bulletin 343 9
at 2.3rrJo Zn, 0.7rrJo Cu and 36rrJo S (ibid.). At Vihanti and Pyhäsalmi, isotopic studies
have been carried out on galenas from the various deposits, on whole rock sampies and mineral separates from the Pyhäsalmi area, on uraniumbearing apatite gneisses at Vihanti and some isolated granitoids southeast of Pyhäsalmi.
Kouvo and Kulp (1961) demonstrated that galena sam pIes from this region differed in isotopic composition from those of either the Outokumpu or Svecofennian type of mineralization, and Vaasjoki (1981) suggested that a regional lead isotopic signature prevailed in galena sampIes within the main sulphide ore belt. Irrespective of the models used (Stacey and Kramers, 1975; Cumming and Richards, 1975) the galena model ages for the various sam pIes range from 1880 to 1970 Ma and are identical within the inherent uncertainties of the lead evolution models. Apart from one sampie collected from the fringe of the ore proper, galenas from the Vihanti mine proved to be isotopically homogeneous. In the Pyhäsalmi area, a granite gneiss registers a V-Pb zircon age of 1930 ± 15 Ma, a synorogenic granodiorite is 1880 ± 15 Ma old and a plagioclase porphyrite has a minimum 207Pbj206Pb age of 1875 Ma (Helovuori, 1979). Pb-Pb whole rock analyses from a sam pIe suite from the mine area suggest an age of 1910 ± 30 Ma for the volcanic rocks associated with the sulphide mineralization (ibid .). A study of the uranium-bearing apatite gneisses from the hanging wall of the Vihanti base metal orebodies (Vaasjoki et al., 1980) showed that the culmination of the regional metamorphism associated with the Svecokarelian orogeny occurred in this area about 1880 ± 5 Ma ago. Granodiorite cobbles from an intraformational conglomerate at Settijärvi have been dated at 1888 ± 7 Ma (Marttila, 1987).
Sampie material
An attempt to sampie the volcanic rocks of the Lampinsaari sequence at Vihanti for zircon V-
Pb analyses failed as no zircon extracts were obtained despite the large sampie size (ab out 100
10 Geological Survey of Finland, Bulletin 343
kg for each of the four sampIes). Thus all the sampIes for mineral V-Pb analyses from the Vihanti area are from rocks outside the mine area or from dykes cross-cutting the Lampinsaari sequence.
Sam pIe A 780 represents an early orogenie basic intrusion, known locally as the Alpua gabbro, which is weIl exposed in its central part. Experience shows that most zircon usually occurs within the more acidic differentiates of basic intrusions (Kouvo, 1976) and therefore, the sampling was conducted from a dioritic portion that c1early forms apart of the gabbro intrusive.
The syntectonic granodiorites are believed to be the oldest felsic rocks in the Vihanti area, and ithas been suggested that some of them at least could be remobilized portions of the nearby Archaean craton. In the outcrop where sam pie A 781 (locally known as the Hirsikangas granodiorite) was collected, the rock is an even grained, slightly orientated gneissose granite, with magnetite-bearing pegmatite veins and sporadic uralitized portions that may be partly assimilated xenoliths of older basic rocks.
About 200 m southwest of the sampling si te for A 781, there is a plagioc1ase porphyrite consisting of (1-2)x(2-5) cm large, zoned (bytownite-andesine) phenocrysts in fine-grained groundmass similar to the early orogenie gabbros . The contact relationship to the syntectonic granodiorite has not been established because of glacial overburden. Sampie A898 was taken to see
whether or not the plagioc1ase porphyrite was related to the locally widespread gabbros.
Another syntectonic plutonic rock in the area is sometimes called a "granodiorite with potassi um feldspar phenocrysts" (Salli, 1964) and sometimes a "microc1ine granite" (Rauhamäki et 01., 1978). The sampie for the zircon age determination (A 782) was collected at Korpi from the main type, wh ich at the sampling location consisted of abundant, slightly orientated potassium feldspar phenocrysts (lx2 cm) in a groundmass of medium-grained quartz, biotite, amphibole and oligoc1ase-andesine.
At Käpylä, 12 km south of the Vihanti ore field, there is a large intrusion of homogeneous, unorientated biotite granite. The rock contains some rare, fine-grained autoliths, occasional potassium feldspar phenocrysts (0.5-1.0 cm) that very rarely have a 0.1-1.0 mm thick oligoc1ase rim. The rock is apparently post-tectonic and a sampie (A899) was taken to determine the duration of the main tectonic activity in the Vihanti area.
A titanite separate from the fault-controlled diabase dyke (A776) transgressing the mineralized sequence was analysed for its lead isotopic composition and uranium and lead concentrations, and two zircon fractions were analysed from a pegmatitic granite dyke (A938) that transgresses the Lampinsaari sequence but is cut by the diabase dyke.
Results and discussion
The results are presented in Figures 1, and 2 and Tables 1 and 2. From these it is evident that:
1) At 1901 ± 12 Ma, the Alpua gabbro is the oldest intrusive rock in the Vihanti area;
2) The felsic syntectonic intrusive rocks (A 781, A 782) register overlapping zircon ag es (1874 ± 13, 1860 ± 13) within experimental error, and thus may be coeval;
3) The geologically youngest rock, the apparently posttectonic Käpylä granite (A899) registers the oldest age (1887 ± 4 Ma) of all the felsic intrusive rocks;
4) The titanite separate from the diabase dyke (A 776) transgressing the Lampinsaari sequence is only slightly discordant and yields a 207Pb/ 206Pb age of 1861 ± 5 Ma which must be a minimum and is only slightly lower than
Geological Survey of Finland, Bulletin 343 11
206Pb/238U
.30
INTRUSIVE ROCKS FROM THE VIHANTI AREA
3.6 207Pb/235U
4 .5
o A780: 1901"!: 12 Ma
+ A781 : 1874 "!:13 Ma
o A782 : 1860"!:13 Ma
x A899: 1887"!: 4 Ma
5.7
Figure I . A concordia plot depicting the results fo r intrusive rocks of the Vihanti area.
206Pb/238U
.30
.22
DIKES AND VEINS FROM THE VIHANTI AREA
3.6
1700
~ + +
207Pb/235U 4.5
o A898: 1878"!: 17 Ma
+ A938: ca. 1865 Ma
o A776: > 1861 Ma
5.7
Figure 2. Mineral U-Ph results for posttectonic dykes and veins in the Vihanti area.
12 Geo1ogical Survey of Finland, Bulletin 343
Table I. U-Pb analyses of minerals from the Vihanti area .
Sam pie Fraction Concentrations 2(l6Pb Lead ratios, 206 = 100
2l8U Pb(tot) 204Pb 204Pb 207Pb 20sPb
A 780 - Alpua gabbro
A780A 4.0-4.2/ -100 876.8 279.21 14550 .00687 11 .595 8.997 B +4.2/-100 522.9 173.47 18730 .00534 11.644 8.948 C 3.8-4.0/ -100 1470.0 430.48 11000 .00909 11.500 8.991 D 3.6-3 .8/-100 1764.3 477.85 13020 .00768 11.421 9.401
A781 - Hirsikangas granodiorite
A781A + 4.21-100 617 .2 184.40 49980 .00200 11.386 8.063 B 4.0-4.21100-150 1047.8 249.19 1860 .05376 11.844 10.973 C 4.0-4.2Imagnetic 998.7 229.19 1460 .06849 12.041 11.110
A 782 - Korpi porphyritic granite
A782A 3.6-3.8/-200 1425 .7 323 .17 691 .14472 13.192 14.530 B 3.8-4.0/ 100-200 1213.7 319.25 772 . 12953 13 .141 12.127 C 4.0-4.21100-200 913.4 257.15 997 .10030 12.655 10.623 D + 4.21100-200 547.1 161.15 1380 .07246 12.478 9.556 E +4.2/-200 606.6 175.40 1060 .09434 12.623 11.274
A898 - Hirsikangas plagioclase porphyrite
A898A +4.3 434.9 160.44 2521 .03966 12.027 16.709 B 4.2-4.3 683.2 245.44 2739 .03651 11.944 16.003 C 4.0-4.2 933.8 331.80 2761 .03621 11.961 18.678
A899 - Käpylä posttectonic granite
A899A + 4.6 299.9 99.50 173 1 .05775 12.248 10.988 B 4.2-4.6 496.6 154.17 1696 .05896 12.217 10.813 C 4.0-4.2 698.6 216.67 1367 .07312 12.391 11.666
A938 - Pegmatite vein
A938A 4.3-4.6 315.4 105 .94 627 .15949 13.458 13.795 B 4.2-4.3 663.3 217.10 615 .16235 13.465 14.789
A776 - Diabase dike
A776A titanite 94.2 30.1 7 629 .15898 13.529 7.854
All data on zircons unless otherwise indicated . Concentrations in IJ.g/g, corrected for blank .
that of the intrusive granites. This result is identieal, within experimental error, with the result from the pegmatite dyke (A938) for which two zireon fraetions suggest a diffusion model age (Wasserburg, 1963) at ab out 1865 Ma;
5) The plagioclase porphyrite (A898) has a zireon age of 1878 ± 17 Ma;
6) There is no indication that any older material was ineorporated into any of the igneous roeks in the Vihanti area.
The lead isotopic eomposition of the zine-Iead ores at Vihanti plots weIl below any average
global lead evolution eurve on the 207Pbj204Pb vs. 206Pb/204Pb diagram involving the uranogenie lead isotopes (Fig.3), a feature that has led several authors (Staeey et al., 1978; Vaasjoki, 1981) to argue that a eonsiderable amount of mantle derived lead was ineorporated into the Vihanti ores. However, on the 208Pbj204Pb vs . 206Pbj204Pb diagram (Fig.3) depieting lead evolution in the complete U-Th-Pb system, the data plot slightly above the average evolution curve, indieating, assuming the plumbotectonics interpretation of Doe and Zartman (1979), that the lead derived from the lower crust. Thus the lead
Geologieal Survey of Finland. Bulletin 343 13
Table 2 . U/ Pb ratios and apparent radiometrie ages for zireons and titanite from the Vihanti area.
Sampie Atomie ratios
206Pb 207Pb 2l8U mu
A780A 0.3025 4.7845 B 0.3183 5.0787 C 0.2817 4.4177 D 0.2595 4.0511
A781A 0.2890 4.5240 B 0.2281 3.4974 C 0.2193 3.3613
A782A 0.2159 3.3700 B 0.2548 4.0024 C 0.2740 4.2701 D 0.2869 4.4999 E 0.2793 4.3723
A898A 0.3285 5.2045 B 0.3221 5.0846 C 0.3119 4.9334
A899A 0.3078 4.8668 B 0.2885 4.5417 C 0.2851 4.4813
A938A 0.2967 4.6099 B 0.2868 4.441 7
A776A 0.3245 5.0815
Atomie ratios eorrected for eommon lead . 6/ 4:15 .15; 7/ 4:15 . 15 ; 8/ 4:34.90
isotopic data imply that the lead of the orebodies evolved at a relatively deep level before their emplacement. A corollary is that if we assume a syngenetic interpretation for the zinc-lead orebodies, the magmas of the volcanic host rocks must have been generated at similarly deep levels. If that is the case, the predominantly dacitic co mposition of the Lampinsaari volcanics (Rouhunkoski, 1968) favours a lower crustal derivation.
At Pyhäsalmi the immediate host rocks of the ores are mica schists presumed to represent metamorphosed pelitic sediments (Helovuori , 1979). However, a wh oie rock Pb-Pb isochron from the local volcanic suite passes through the galena lead isotopic composition and is thus consistent with a cogenetic origin of the sulphides and the volcanic rocks. Also, the sulphur isotopic composition within the massive ore is relatively uniform (834S ranges from + 5 to + 10 per mil CDT,
Apparent ages (Ma)
207Pb T(6/ 8) T(7/ 5) T(7/ 6) 206Pb
0.1150 1704 1781 1880 0.1157 1782 1831 1891 0.1138 1600 1720 1862 0.1133 1487 1645 1853
0.1135 1637 1736 1857 0.1112 1325 1527 1819 0.1112 1278 1496 1819
0.1132 1260 1497 1851 0.1140 1464 1634 1865 0.1148 1562 1687 1878 0.1151 1626 1731 1882 0.1151 1589 1702 1882
0. 1149 1831 1853 1878 0.1145 1799 1833 1872 0. 1147 1750 1807 1875
0 .1147 1730 1796 1874 0. 1142 1633 1738 1867 0 .1140 1616 1727 1864
0 .1127 1675 1751 1843 0 .1123 1625 1720 1837
0 .1138 1812 1834 1861
averaging 7.5 per mil; Helovuori, 1979) thus suggesting a significant input of seawater to a magmatic source. Therefore a submarine volcanogenic origin for the Pyhäsalmi deposit seems highly probable. Relatively old sulphur isotopic analyses from a limited nu mb er of sampies from Vihanti (Rouhunkoski , 1968) exhibit values similar to those from Pyhäsalmi, but unfortunately the only up to date sulphur isotope data from the Vihanti area are from wall rocks (Rehtijärvi et al., 1979), not the ores.
The radiometrie age data from the Vihanti and Pyhäsalmi areas coincide in many ways: the ages of the gabbros are similar, the plagioclase porphyrites from both districts are coeval within experimental error and , apart from some slightly younger titanites found at Pyhäsalmi, there is only one noteable difference: at 1930 ± 15 Ma, the zircon age from the tonalitic Kettuperä gneiss
14 Geological Survey of Finland, Bulletin 343
208Pb/204Pb
35.1
0
0 Q).
36.7 r 15.1
207Pb/204Pb
15.3
15.2
000 o
0
206Pb/204Pb 15.5
Vihol a nniemi o
o o Mai n sulphide ore belt
15. 1
15. 1 206Pb/204Pb
15.5
o
15.9
15.9
Figure 3. Average lead iSOLOpic compositions of galenas from base metalores and prospects within the Raahe-Ladoga zone.
at Pyhäsalmi (Helovuori, 1979) is about 50 Ma older than any of the intrusive granitoids at Vihanti.
The similarities in the radiometric ages, the lead isotopic compositions and the sulphur isotope values observed at Vihanti and Pyhäsalmi suggest that these base metal deposits were formed by similar mechanisms. Combined with other geological information, the isotopic evidence implies that the sulphides were formed by volcanogenic seafloor exhalations about 1900 Ma ago and were deformed during the intrusion of gabbros and granitoids between 1900 and 1880 Ma ago. The regional metamorphism associated with the intrusive activity peaked at 1880 Ma, and
Geological Survey of Finland , Bulletin 343 15
no significant remobilization of the sulphides has occurred since that time.
The cobbles from the Settijärvi conglomerate are 1888 ± 7 Ma old and demonstrate that syntectonic granitoids were incorporated into this rock and thus suggest that they were extensively weathered (Marttila, 1987). As there is some outcrop evidence suggesting that the conglomerates are intersected by the plagioclase porphyrites, the resuIts imply relatively rapid large scale vertical movements. The ages of the Käpylä granite and the fault controlled pegmatite and diabase dykes at Vihanti suggest that all tectonic activity in the northwestern part of the RaaheLadoga zone had ceased by 1860 Ma at the latest but possibly already by 1875 Ma.
PIELA VESI AND RAUTALAMPI: BLOCK MOVEMENTS AND CONTACT METAMORPHISM
Geological setting and previous isotopic work
There are two basic differences between the Pielavesi-Rautalampi and Vihanti-Pyhäsalmi districts: first, the Pielavesi-Rautalampi district lies much closer to established Archaean outcrop than the latter, ~md, secondly, it is characterized by weil defined block structures evident in abrupt changes in the metamorphic mineral paragenesis (Korsman et al. , 1984; Hölttä, 1988). K-Ar analyses (Haudenschild, 1988) suggest that these movements lasted for a considerable period after the culmination of the Svecokarelian orogeny. These features make it impossible to establish a clear cut stratigraphy for the area. As a general rule, the supracrustal sequence consists of acid and basic volcanic rocks underlying a metasedimentary pile (Marttila, 1981). The intrusive rocks comprise gneissose tonalites, gabbros, hypersthene granites and porphyritic granites .
Base metal mineralization occurs frequently throughout the Pielavesi-Rautalampi area.
Though none of the prospects are currently economically viable, some of them are a fair size. Thus Säviä at Pielavesi has proven reserves of 4 Mt at 1.1 % Cu and 2.5% Zn (Salli, 1983), Kalliokylä at Kiuruvesi contains 1.5 Mt at 0.4% Cu and 2.5% Zn, and Hallaperä (Kiuruvesi) has about 3.5 Mt at 0.5% Cu and 1.1 % Zn (Marttila, 1981). Other prospects extensively investigated are Kangasjärvi (Kumpuselkä) at Keitele and Pukkiharju at Rautalampi. The galena lead isotopic compositions are identical to those of Vihanti and Pyhäsalmi and internally are homogeneous at least within the Kangasjärvi mineralization (Table 3).
The oldest rocks encountered in the Pielavesi-Rautalampi area are tonalitic gneisses, one of which has been dated at 1922 ± 12 Ma (Korsman et al. , 1984). These rocks are regarded as the basement of the overlying volcanosedimentary supracrustal sequence (e.g. Papunen, 1986). The
16 Geological Survey of Finland , Bulletin 343
Table 3. Lead isotopic analyses of galenas from the Raahe-Ladoga zone.
Occurrence 206Pb/ 204Pb 2°'Pb/ 204Pb 2osPb/204Pb
Lampinsaari, Vihanti 15 .150 15.147 34.896 Pyhäsalmi, Pyhäjärvi 15 .111 15.147 34.835 Säviä, Pie1avesi 15 .102 15 .115 34.771 Jylhä, Pielavesi 15.128 15.145 34.805 Kangasjärvi, Keitele 15 .140 15.135 34.804 Pukkiharju, Rautalampi 15 .091 15.125 34.765 Viholanniemi, Joroinen 15.284 15.155 35.030 Pirilä, Rantasalmi 15.640 15 .280 35 .090
Data normalized to the accepted values of CIT and NBS SRM981 standards.
supracrustal formation is intruded by both diorites and hypersthene bearing granites which have been dated at 1880-1890 Ma (Salli, 1983 ; Korsman et al. , 1984). According to Marttila (1976 and 1981), these are cut by ophitic gabbros and diabases registering a zircon U-Pb age of 1886 ± 5 Ma. A titanite from a skarn at Rytky has an almost concordant U-Pb age of 1870 Ma (Marttila, 1976).
The quartz diorite from Molkanjärvi, dated at 1882 ± 4 Ma has been analysed for its Nd isotopic composition and has an E(Nd) value of 1.4-0.9 signifying a fairly substantial input of early Proterozoic mantle material (Huhma, 1986). A sampie from the Onkivesi granite/granodiorite (ibid.) right on the Archaean-Proterozoic contact, has a significantly lower E(Nd) at 3.6-0.9 but is still not as negative as the theoretical value of 10 for 2700 Ma old continental crust at 1900 Ma.
SampIe material
Marttila (1976) reported a total fraction zircon U-Pb age for the Lammasaho granodiorite (A6oo). This determination has now been improved by analysing four fractions separated from the original material.
The Laajamäki quartz diorite (A83) intersects the supracrustal formation in the central part of the Pielavesi map sheet. About 700/0 of the rock consist of oligoclase-andesine. The amount of
quartz is minor, and hypersthene, diopside and biotite are the mafic constituents. The text ure of the rock is hypidiomorphic and the weathered surfaces are often a brownish colour. Accessory minerals are apatite, epidote and zircon (Salli, 1983).
The southern margin of the roundish Vaaraslahti granite (Salli, 1983) is in contact with metapelitic rocks, which exhibit adefinite contact metamorphic zoning (Hölttä, 1988). The effects of contact metamorphism were studied on two sampies, one taken from the contact (A1026) and one from the garnet-cordierite zone (A1025).
In order to compare the timing and effects of metamorphism within the various blocks of the Pielavesi-Rautalampi area a garnet-cordieriteorthopyroxene rock was sampled at Sahinperä (A1028) in the Pielavesi block (cf. Korsman et al., 1984; Hölttä, 1988).
East and north of the township of Rautalampi there is a body of granitoid rocks stretching ESE-WNW over a distance of 5 km and averaging 0.5 km in width. It contains 1-20 cm thick amphibolitic sheets and, judging from these, has been subjected to the same deformationaI phases as the enclosing metasedimentary-metavo1canic sequence. A sampie (AI075) of the granitoid portion was collected at Pyöreänsuonvuori to clarify the age relationship of this rock to the Rastinpää intrusion (Korsman et al., 1984) and the 10caI metavolcanic rocks.
Geological Survey of Finland, Bulletin 343 17
Results and discussion
The results for the Pielavesi-Rautalampi area are summarized in Tables 4 and 5 and Figures 4 and 5. They demonstrate that: 1) At 1923 ± 4 and 1914 ± 4 Ma, respectively, the
quartz diorite from Laajamäki (A83) and the sill-like granitoid body represented by the
sampie from Pyöreänsuonvuori (A1075) are the oldest in the present material;
2) Of the two metapelite sampies from the contact aureole of the Vaaraslahti intrusion, the one farther from the contact (A1025) contains a zircon with ages in excess of that of
Table 4. U-Pb analyses of zircons from the Pielavesi-Rautalampi area.
Sampie Fraction Concentrations 206Pb Lead ratios, 206= 100
2l8U PbCtot) 204Pb 204Pb 207 Pb 20sPb
A83 - Laajamäki granodiorite A83A 4.3-4.5/HF C*) 452.3 144.65 27100 .00369 11. 774 8.867
B 4.3-4.5 C*) 467 .0 149.28 8762 .01141 11.886 9.172 C 4.2-4.3/HF C*) 650.0 182.84 12842 .00779 11.806 9.505 D 4.3-4.55/ abr 457.7 152.22 8734 .01145 11.891 9.421
A0600 - Lammasaho quartzdiorite
A600A + 4.2/150-200 C+ ) 1392.8 424.65 2948 .03392 11.736 9.826 B + 4.3 495 .6 164.20 4502 .02221 11.580 11.221 C 4.2-4.3/ HF 614 .0 210.05 5202 .01922 11.593 11.293 D 4.0-4.2 1093 .0 413.41 342 .29266 15.228 20.129 E 4.0-4.2/ HF 878.1 303 .10 4536 .02205 11.626 11.150
A1025 - Yijäkönmäki metapelite, 80 m from contact
A1025A + 4.53 399.1 168.85 1132 .08827 13 .755 31.184 B 4.3-4.53 510.3 198.82 1468 .06808 13 .512 11.044 C 4.2-4.3 732. 7 300.41 703 . 14225 14.607 13.428 D 4.0-4.2 1337.7 527.74 1001 .09988 13 .901 12.981 E monazite 2460.6 3876.73 11.548 421.67
AI026 - Yijäkönmäki metapelite, contact to hypersthene granite
AI026A 4.2-4.3 1004.1 360.75 9413 .01062 11.686 12.017 B 4.3-4.6 451.5 209.67 16318 .00613 11.646 47.066 C 4.0-4.2 448.4 565 .22 4419 .02263 11.755 13 .651 D monazite 1793 .9 3211.1 105670 .00095 11.503 507.07
AI028 - Sahinperä garnet-cordierite-orthopyroxene rock
AI028A + 4.58 319.2 160.9 373600 .00027 11.504 66.49 B 4.3-4.58 319.1 105 .12 52740 .00190 11.551 2.1 61 C 4.2-4.3 702.0 225.32 26700 .00375 11.530 .775 D 4.0-4.2 1019. 1 318.45 18170 .00550 11.509 .661 E monazite 2607.1 4396.90 30760 .00325 11.500 461 .02
AI075 - p yöreänsuonvuori granitoid
AI075A + 4.5 / abraded 151.5 53.48 11.708 7.360 B +4.5 163 .7 55.48 11.675 7.079 C 4.3-4.5/ + 100 304.8 104.61 50610 .00198 11 .694 7.809 D 4.2-4.3/ + 100 567.5 198.76 28280 .00354 11 .684 10.143 E 4.0-4.2/100-200 1000.4 304.20 15560 .00643 11.593 6.713
All data corrected for blank. Concentrations in Ilg/ g. (*) From Haudenschild (1985) C +) From Marttila (1976)
2
18 Geologieal Survey of Finland, Bulletin 343
Table 5. U/ Pb ratios and apparent radiometrie ages for zireons and monazites from the Pielavesi-Rautalampi area.
SampIe Atomie ratios
206Pb 207Pb 238U 235U
AOO83A .3060 4.9470 B .3048 4.9300 C .2903 4.6830 D .3159 5.1123
A0600A .2879 4.4762 B .3103 4.8253 C .3203 5.0043 D .3071 4.7675 E .3233 5.0497
AI025A .3318 5.7579 B .3571 6.2084 C .3612 6.3373 D .3531 6.1234 E .3389 5.3953
AI026A .3346 5.3261 B .3368 5.3700 C .3224 5.0906 D .3318 5.2563
AI028A .32560 5.1687 B .33449 5.3151 C .32993 5.2219 D .32150 5.0687 E .33767 5.3338
AI075A .34229 5.5254 B .32936 5.3038 C .33146 5.3318 D .33164 5.3209 E .29644 4.7029
Atomie ratios eorreeted for eommon lead . 6/ 4:15.15 ; 7/ 4:15 .15; 8/ 4:34.90
the intrusion, while the zircons in the immediate contact (A1026) have been reset to give the age of the intrusion within experimental error.
3) The monazite from A1025 has an age of 1887 ±4 Ma and the one from A1026 an age of 1879±3 Ma;
4) The zircons from the regionally metamorphosed garnet-cordierite-orthopyroxene rock at Sahinperä yield a V-Pb age of 1889 ± 13 Ma whereas its monazite has an age of 1873 ± 3 Ma;
5) At 1853 ± 12 Ma, the granodiorite from Lam-
207Pb 206Pb
.1172
.1173
.1170
.1175
.1128
.1128
.1133
.1126
.1133
.1126
.1261
.1273
.1258
.1155
.1154
.1156
.1145
.1149
.1150
.1153
.1148
. 1143
.1146
.1171
. 1168
.1167
.1164
.1151
Apparent ages (Ma)
T(6/ 8) T(7 / 5) T(7/ 6)
1722 1810 1914 1715 1808 1915 1644 1764 1911 1769 1838 1916
1631 1726 1844 1742 1789 1844 1791 1820 1853 1726 1779 1842 1805 1827 1852
1847 1940 2041 1968 2005 2044 1987 2023 2060 1949 1993 2039 1881 1884 1887
1860 1873 1886 1871 1880 1890 1801 1834 1872 1847 1861 1878
1818 1847 1880 1860 1871 1884 1838 1856 1876 1797 1830 1869 1875 1874 1873
1897 1904 1912 1835 1869 1907 1845 1873 1906 1846 1872 1901 1673 1767 1881
masaho (A600) is the youngest of the present sampie material.
The result for the Laajamäki quartz diorite (A83) is basicaUy a three point isochron, as two of the data points crowd together and thus the abraded fraction, D, is determinative for the age. However, the results for both A83 and A1076 are coeval with the well established age of 1922 ± 12 Ma for the Rastinpää tonalitic gneiss (Korsman et a/., 1984). Considering that Laajamäki is located on the northeastern side of the Iisvesi fault but that Rastinpää and Pyäreänsuonvuori lie on the southwestern side, it seems certain that
Geological Survey of Finland, Bulletin 343 19
206Pb/238U
GRANITOIDS IN THE PIELAVESI-RAUTALAMPI AREA
.30
3.6 207Pb/235U
4.5
o A0083: 1923 t 4 Ma
+ A1075: 1914t4 Ma
o A0600: 1853 t 8 Ma
5.7
Figure 4. Zircon V-Pb resuIts fo r granitoid rocks of the Pielavesi-Rautalampi district.
206Pb/238U
METASEDIMENTS FROM THE PIELAVESI-RAUT ALAMPI AREA
.37
2000 0
0
monazites
~90~ d/
/'fP~ -V 0 0
" o A 1025: not re set /0
or + A 1026: 1895 t1 Ma /'
o A1028: 1889 t 13 Ma
.31 207Pb/235U
5.1 6.0 6.8
. ..,....
Figure 5. Mineral V-Pb de[erminations on metavo1cano(?)metasedimentary rocks in [he Pielavesi-Rautalampi area.
20 Geological Survey of Finland, Bulletin 343
the ca. 1920 Ma granitoid activity was relatively common throughout the Pielavesi-Rautalampi area.
The metapelite sampies (AI025, A1026) from the contact aureole of the Vaaraslahti intrusion register different zircon ages with 1892 ± 5 Ma for the contact sam pie (A1026) and older ages for the one farther away (A1025). As is usual for zircons from a dry environment, the analyses from the contact sam pie are relatively concordant. The monazite age from A1025 is, at 1887±4 Ma, marginally lower than the ages for the zircons. Thus, within experimental error, the zircons from the contact sampie and the monazite from the metapelites farther away are coeval with the zircons of the intruding hypersthene granite dated at 1884 ± 5 Ma (Sa1li, 1983) and reflect the temperature peak of these rocks. The somewhat lower monazite ages for the intrusion (1874 Ma) and the contact sampie (1878 Ma) can be interpreted as the cooling age of the granite. As the probable blocking temperature of monazite is 500-600°C (Odin, 1976), the monazite results indicate that no regional thermal event exceeding that temperature range has occurred within the Vaaraslahti block since probably 1885 Ma aga and certainly not since 1875 Ma ago.
The results from the two metapelite sam pies from the contact aureole of the Vaaraslahti intrusion thus demonstrate that a K-feldspar-garnetcordierite grade of metamorphism is insufficient to totally reset detrital zircons. Only at the immediate contact of the hypersthene granite, where the temperature has approached 800°C, has total resetting occurred.
The zircons from the garnet-cordierite-orthopy-
roxene rock at Sahinperä (AI028) register a UPb age of 1889 ± 13 Ma. As Sahinperä lies within the Pielavesi block, this result may not be directly applicable to the regional metamorphism within the Vaaraslahti block, but even so it demonstrates that the time difference between the intrusion of the hypersthene granites and the preceeding regional metamorphism within the PielavesiRautalampi area is very short. The monazite age of 1873 ± 5 Ma may be interpreted as reflecting the regional cooling through the 500-600°C range.
The ophitic gabbro at Tuli-Toiviainen and its kindreds exhibit chilIed margins towards their country rocks. They generally occur as dykes and laccoliths, and, according to Marttila (1976 and 1981) they crosscut the hypersthene-bearing granitoids. The age of the gabbro at Tuli-Toiviainen, 1886 ± 5 Ma, is consistent with this notion but also requires rapid regional cooling, a constraint supported by the monazite data.
The age of the Lammasaho granodiorite (A600) is surprisingly low as this rock has been considered part of the gneiss complex forming the basement of the volcano-sedimentary sequence (Marttila, 1976 and 1981). To overcome the stratigraphic difficulty, Marttila (ibid.) attributed the young zircon age of the rock to remobilization of the basement during the late orogenic phase of the Svecokarelian folding. This problem could possibly be solved by Sm-Nd analyses. However, for the present study the question of the stratigraphic position of the Lammasaho granodiorite is immaterial. As the rock exhibits very little or no deformation, the zircon age of 1853 ± 12 Ma sets a minimum for the end of the tectonic activity within the Lampaanjärvi block.
FROM JOROINEN TO SULKA V A: EFFECTS OF PROGRESSIVE MET AMORPHISM
Geological setting and previous isotopic studies
The southeastern end of the Raahe-Ladoga which is transitional between the Svecofennian zone forms part of the socalIed Savo schist belt, and Karelian supracrustal domains in Finland.
The progressive metamorphism in the area was discovered as a result of the 1: 100,000 geological mapping program and has since been studied in detail by Korsman (1977) and Korsman et al. (1984).
The metamorphic grade in the area increases from north to south and has been established on the basis of mineralogical observations on metapelites. Particularly in the northern mica schist zone the metapelites have preserved features of their turbiditic origin such as graded bedding, which gradually disappear as the metamorphic grade increases. Thus bedding is still recognizable in the K-feldspar-sillimanite zone, but graded bedding has been obliterated by the formation of sillimanite. Migmatization sets in within the garnet-cordierite-biotite zone, where K-feldspar is often poikiloblastic. In the garnet-cordieritesillimanite zone the proportion of migmatizing granite increases, the gneissose sections are often separated from each other by granitic segregations and the K-feldspar is no longer poikiloblastic. Furthermore, the cordierite is often pinitized and K-feldspar sericitized while the lower grade zones are almost devoid of signs of retrograde alteration. Korsman et a/. (1984)
estimate a geothermal gradient of about 50o e / km for the area.
The stratigraphic position of voicanic rocks in the Joroinen-Sulkava area is not absolutely certain. Acidic rocks mapped as quartz-feldspar schists and of probable voicanogenic origin underlie mafic-ultramafic lavas that occasionally exhibit pillow structures (Kousa, 1985). The metavoicanic sequence probably lies stratigraphically below the metapelite sequence and is in any case definitely older than the syntectonic tonalites.
The Joroinen-Sulkava area differs from other parts of the Raahe-Ladoga zone in the paucity of base metal mineralization, although Ni ores associated with gabbros occur with regular frequency (cf. Tontti, 1981). Thus the gold prospect at Pirilä and the Zn target at Viholanniemi are the only known occurrences in the area which contain any base metal accumulations
Geological Survey of Finland , Bulletin 343 21
worth speaking of; neither one of them is considered economic at present.
Korsman et a/. (1984) reported a number of V-Pb zircon ages from the Rantasalmi-Sulkava district. The tonalite at Tuusmäki, which precedes the progressive metamorphism, gives a normal Svecokarelian syntectonic age of 1888 ± 15 Ma. The migmatite from Säviönsaari, in the centre of the Sulkava thermal dome, yields ages of 1810 ± 7 and 1833 ± 16 Ma for palaeosome and neosome, respectively. Monazites in the same sampies are between 1820 and 1840 Ma old. A definitely post-tectonic granodiorite from Hirvensalo registers a zircon age of 1802 ± 22 Ma and contains an almost concordant titanite dated at 1764 ± 19 Ma. In the Haukivesi block, just northeast of the study area, there are hypersthene granites dated to be about 1890 Ma old (patchett and Kouvo, 1986). The whole rock c (Nd) value of -0.6 and zircon c (Hf) result of + 1.6 suggest that a large part of the material for this rock is of mantle derivation.
About 2 km west of the sampling site for A1013 (see next section), a trondhjemitic tonalite at Saunakangas has been dated at 1903 ± 10 Ma (Huhma, 1986). However, geophysical data suggest that this rock may not belong to the same block with the progressively metamorphosed rocks of the Joroinen-Sulkava area (Korsman et a/., 1988).
Sm-Nd analyses of the Saunakangas tonalite give an c(Nd) value of 3.3 ± 0.5, which is suggestive of an origin from adepleted mantle source (Huhma, 1986). Similarly, about 15 km east of the Joroinen-Sulkava area, the Ni-bearing Laukunkangas gabbro has been dated at 1880 Ma and exhibits an c(Nd) value of 0.2 ± 0.5 (ibid.). A sampie from the post-tectonic Puruvesi granite, about 30 km farther east, has a zircon V-Pb age of 1797 ± 19 Ma (Nykänen, 1983) and exhibits an c(Nd) value of -6.9 ± 0.8, which is indicative of a significant Archaean crustal component in its source (Huhma, 1986).
The few ore lead isotopic analyses from the Joroinen-Sulkava area differ markedly from the
22 Geological Survey of Finland, Bulletin 343
others in the Raahe-Ladoga zone (Table 3). zations of the central Finnish batholith area (cf. Moreover, the leads from Viholanniemi and Pi- Vaasjoki, 1981), whereas the Viholanniemi lead rilä are different from each other: Pirilä has a is intermediate between this group and the leads lead isotopic composition similar to the minerali- of the Vihanti-Pyhäsalmi ore zone.
Sampie material
Partly to study the effects of regional metamorphism on the detrital zircons in the metapelites and partly to investigate their provenance, two sampies were collected from the metapelites. The one from Vuotsinsuo (AI5) represents the mica schist zone and the one from Härkälä (A1022) the northern part of the garnet-cordierite-biotite zone. The latter sampie also contained some monazite.
A quartz-feldspar schist from Viholanniemi was sampled as a representative of the acid volcanic rocks . The porphyric texture of the rock
(AlO13) is evident in hand specimen, and flow textur es around the feldspar phenocrysts can be observed in thin section. This rock is also host to the Viholanniemi base metal mineralization.
A reddish granite intersects the metapelites in the K-feldspar-sillimanite zone exhibiting structures typical of the D3 deformation phase dose to the Pirilä gold prospect (Kilpeläinen, 1988). A sampie from this granite (A1099) was collected to determine a minimum age for this deformation phase.
Results and discussion
The results are summarized in Tables 6 and 7 and Figures 6 and 7. It is apparent that:
1) The zircons from both metapelites (AI5-Vuotsinsuo and A1022-Härkälä) are definitely
Table 6. U-Pb analyses of sampIes from the Joroinen- Sulkava area.
Sam pIe Fraction Concentrations 206Pb Lead ratios, 206 = 100
238U Pb (tot) 204Pb 204Pb 207Pb 208Pb
AI5 - Vuotsinsuo micaschist (metapelite)
AOOl5A + 4.5/ +200 145.9 58 .52 2358 .04241 14.950 18.012 B 4.3-4.5/ + 100 289.1 112.78 3318 .03014 14.379 14.389 C 4.2- 4.3/ + 200 525 .1 189.69 3431 .02915 14.217 13.160
AI022 - Härkälä cordierite gneiss (metapelite)
AI022A 4.3- 4.55 475.7 169.1 7 2662 .03756 13.036 9.228 B 4.2-4.3 855.4 295.66 1551 .06448 13.278 10.092 C 4.0- 4.2 1314.7 437.45 1056 .09474 13 .565 11.473 D monazite 7613.8 5292.83 86850 .00115 10.997 139.617
AI013 - Viholanniemi metarhyolite
AI013A + 4.55 149.7 52.22 5616 .01780 11.876 12.613 B 4.3- 4.55/ + 200 236.9 80.47 8024 .01246 11.799 14.715 C 4.2- 4.3/ -150 495 .9 139.26 3924 .02548 11.876 18.793
A 1099 - Pirilä granite
Concentrations in Jig/ g; corrected for blank .
Geologieal Survey of Finland, Bulletin 343 23
Table 7. U/ Pb ratios and apparent radiometrie ages for sampies from the Joroinen-Sulkava area.
Sampie Atomie ratios
206Pb 238U
Aoo15A .34557 B .34792 C .32573
AI022A .33368 B .31995 C .30235 D .31877
AI013A .32249 B .30919 C .24695
Atomie ratios eorreeted for eommon lead. AI013: 6/ 4:15 .15 ; 7/ 4:15.15; 8/ 4:34.9
207Pb 235U
6.8561 6.7055 6.2109
5.7642 5.4730 5.1203 4.8260
5. 1743 4.9587 3.9270
A15 and A1022: 6/ 4:15 .68; 7/ 4: 15.46; 8/ 4:35.27
206Pb/238U
Apparent ages (Ma)
207Pb T(6/ 8) T(7/ 5) T(7/ 6) 206Pb
.1439 1913 2092 2274
.1398 1924 2073 2224
.1383 1817 2005 2206
.1253 1856 1941 2033
.1241 1789 1896 2015
.1228 1702 1839 1997
.1098 1783 1789 1796
.1164 1801 1848 1901
.1163 1736 1812 1900
.1153 1422 1619 1885
MET APELITES FROM THE JOROINEN-SULKAVA AREA
o 0 .34
+ monazite o
.28 o AOO 15 - Vuotsinsuo
+ A 1 022 - Härkälä
207Pb/235U 5.0 6 .6
Figure 6. Zireon and monazite U-Pb data from the metapelites of the progressively metamorphosed JoroinenSulkava distriet.
older than the intruding granitoids, with the less metamorphosed sam pie (A15) containing the fractions with the oldest apparent ages;
2) The monazite of the sam pie from the garnetcordierite-biotite zone (Al022) has an almost concordant age of 1796 ± 5 Ma;
24 Geological Survey of Finland, Bulletin 343
206Pb/238U
IGNEOUS ROCKS FROM THE JOROINEN- SULKAVA AREA
1900~
~~ . . 30
. ~ /,
.22
.~ .
o o A 1013: 1906"!:4 Ma
+ A 1099: 1815"!:7 Ma
207Pb/235U 4.5 5 .7
Figure 7. Zircon U-Pb results from the Viholanniemi meta rhyo lite and the Pirilä granite in the Joroinen-Su lkava district.
3) The granite intersecting the 0 3 deformation (Al099) yields a zircon age of l8l5±7 Ma;
4) The acid metavo1canic rock from Viholanniemi (Al013) has a zircon age of 1906±4 Ma.
The detrital zircons in the metapelites become progressively younger as the grade of regional metamorphism increases. Thus the 207Pb/206Pb ag es of the zircons range from 2200 to 2300 Ma in the mica schist zone (A15) but are no more than about 2000 Ma (AI022) in the garnet-cordierite-biotite zone. In the middle of the Sulkava thermal dome (Säviönsaari, Korsman et al., 1984), the zircons are totally reset in granulite facies metamorphism.
We believe that the zircons have roughly the same origin. This is largely because of their morphological similarities, as in all the fractions analysed the majority of the crystals consist of semi-euhedral tetragonal prisms terminating in pyramid surfaces rounded by abrasion during
transport. The typical length/ breadth ratio is about 2 and the dominant colour is brown although some reddish pigment occurs intermittently.
If the above thesis of a common origin for the zircons in all the metapelites of the JoroinenSulkava area is accepted, it follows that the 207Pb/206Pb age of the least metamorphosed zircons, namely those in sampie A15, is the minimum age for their original material. As even the zircons of A15 must have lost some lead, it is unlikely that they derive from the Jatulian (2100-2200 Ma) vo1canic rocks although albititic varieties of these rocks contain appreciable amounts of zircon. The next youngest candidates could be the feldspar porphyries (2350 Ma) that cross-cut the Sumi-Sariolian rocks in Soviet Karelia (Kratz et al. , 1976). However, although Pekkarinen (1979) recorded the possible existence of these rocks in Finland, they are not widespread,
and the zircons from neither A15 nor A1022 have a morphology indicating volcanic origin. Thus the most likely source for the zircons of the metapelites in the J oroinen-Sulkava area is the granitoids of the Archaean basement (> 2500 Ma) complex.
We emphasize that the above reasoning applies only to zircons, which during weathering and transport are among the most resistant phases. As demonstrated by Huhma (1987), the E(Nd) values for both the Kalevian turbidites and the metasediments of the Tampere region imply that they consist principally of material younger than the Archaean. Although no Sm-Nd data exist for the Joroinen-Sulkava area, it is hardly conceivable that their E(Nd) values would differ significantly from those of the other Svecokarelian metasediments. Considering the distribution of REE among the various mineral species commonly present in pelitic sediments, we conclude that the bulk of the metasediments in the Joroinen-Sulkava area probably contain material derived from rocks formed from mantle material between 2100 and 1910 Ma ago .
As at Vaaraslahti, it is apparent that even an intense garnet-cordierite-sillimanite-biotite grade of metamorphism is insufficient to totally reset the zircon V-Pb systems. Only at Säviönsaari in the centre of the Sulkava thermal dome, where the temperature has exceeded 750°C, were the zircons reset.
The preceding results agree with findings from the Tampere schist belt, where detrital zircons in a micaschist inclusion in the centre of a 1880 Ma old granodiorite still exhibit an age of about 2300 Ma (Wetherill et al., 1962). Similarly, a granulite at Myösäjärvi in Lapland (Meriläinen, 1976) contains two zircon generations of slightly different
Geological Survey of Finland, Bulletin 343 25
ages, the detrital one being older whereas the younger one has the same age as the metamorphic monazite. Thus the finding that zircons retain most of their radiogenic lead during prolonged heating at temperatures exceeding 600°C (Mattinson, 1982) may be amended by the statement that in many cases lower granulite facies conditions are insufficient to totally reset detrital zircons.
This conclusion does not necessarily contradict other findings (e.g., Gebauer and Grünenfelder, 1976) which indicate that some zircons have lost large amounts of radiogenic lead al ready in greenschist facies conditions. In these cases the resetting is not total. Furhtermore, excessive amounts of OH-groups (e.g., Grünenfelder et al., 1968) and common lead (Vaasjoki, 1977) seem to influence the degree of discordancy of zircons. It is therefore probable that zircons with initially disturbed lattices are more easily reset during metamorphism than those whose structure approaches the ideal configuration. We therefore conclude that the partial resistivity of zircons in high-grade metamorphism is rather the rule than the exception.
For the acid metavolcanic rock at Viholanniemi (A1013), neither its age nor its association with base metal mineralization presents any surprise. However, the galena lead isotopic composition of the mineralization is somewhat different from that prevailing in the Raahe-Ladoga zone from Vihanti to Rautalampi. Even more significantly, at Pirilä, only 15 km east-southeast of Viholanniemi, the galena lead is typical of the Central Finnish batholith area. Thus, over a relatively short distance, there is a marked increase in the crustal component in base metal mineralization.
CRUSTAL EVOLUTION ALONG THE ARCHAEAN-PROTEROZOIC BOUNDARY
Several authors have proposed plate tectonic models for the Fennoscandian (Baltic) Shield.
Piirainen (1975) suggested a suture dipping NE along the Archaean-Proterozoic boundary, while
26 Geological Survey of Finland, Bulletin 343
Hietanen (1975) proposed a suture in the same environment and an island are embracing the SW Finnish and central Swedish Svecofennian supracrustal rocks. Gaal and Gorbatschev (1987) suggested a basically Andean type collision model for the Svecokarelian (in their terminology the Svecofennian) orogeny.
On the other hand, for lack of evidence, many geologists contest the applicability to the Precambrian of plate tectonic principles as observed today (e.g., Windley, 1977; Miyashiro et a/., 1982). Thus Kröner (1977) and McWilliams and Kröner (1981) have suggested a mechanism for Proterozoic intraplate orogenies whereby, after the initial break-up of the continental plate, all processes of subsidence and deformation would occur within the continental mass, and the horizontal distances during the processes would be relatively short. Recently Edelman and J aanusJärkkälä (1983) and Brannigan (1987) have interpreted tectonics in southwestern Finland using such a model. The one point most students of the Precambrian seem to agree on is that during the early development of the Earth, crustal nuclei were formed that served as "backbones" of the continents (e.g., Moorbath, 1985).
Sm-Nd results obtained by Huhma (1986) indicate that the roughly 1.9 Ga old granitoids of the Karelian province, lying northeast of the Raahe-Ladoga zone, contain a significant crustal component presumably derived from the Archaean, whereas equivalent rocks of similar age in the Svecofennian province exhibit much higher e(Nd) values and therefore must contain a large Proterozoic mantle component. Similarly, a study of sedimentary provenances indicates short crustal residence times for the Proterozoic material in the Tampere Schist Belt, whereas rocks from the Karelian province contain a higher Archaean component (Huhma, 1987). Thus these Sm-Nd results strongly suggest that juvenile Proterozoic material was rapidly added to the margin of the Archaean plate during the Svecokarelian orogeny, which culminated about 1.9 Ga ago .
A similar picture emerges from lead isotopic
studies of galenas . Leads from the Svecofennian domain and the ophiolite-related Outokumpu deposit are deficient in 207Pb and form adefinite linear trend. The Karelian and Archaean leads found northeast of the Raahe-Ladoga zone, in contrast, contain an excess of this isotope, and therefore appear to be derived from an older crustal source (Vaasjoki, 1981). Furthermore, palaeomagnetic data from the Raahe-Ladoga zone and the Archaean Varpaisjärvi area are fundamentally different from each other (Neuvonen et al., 1981) and hence argue for different geological and thermal histories for these two areas.
Should an intraplate orogenie model be correet for the Svecokarelian orogeny, one would expect the isotopic data to be rat her symmetrically distributed. A probable distribution would be a relatively narrow belt of mantle-related lead and neodymium signatures enclosed on either side with data indicating fairly long crustal residence times for their material. However, the data from Finland are definitely asymmetrie in distribution. In southern Sweden, there is no indication of any crust older than Svecokarelian, as the younger Gothian and Sveconorwegian provinces have been added to the margin of the Fennoscandian Shield (Lindh, 1987). The only report of older material within the Svecofennian province concerns so me ancient cores in zircons of the Vehmaa rapakivi batholith (Vaasjoki, 1977) which at best can represent only a very minor volume of the Svecofennian province. For the evolution of the Fennoscandian Shield in lower Proterozoic times isotopic results overwhelmingly favour a model according to wh ich juvenile material was added to an older crustal core at an active continental margin. The mechanism may have been similar to the plate tectonic processes commonly observed in Phanerozoic environments.
However, though plates and tectonics must have existed throughout the Precambrian, exact analogies cannot and should not be drawn from present observations. One fact that should be
borne in mind is that, according to geological evidence, the conductive geotherm for continental crust in the Precambrian was similar to that observed today and, consequently, because of higher heat generation, recycling of oceanic plates must have been faster (e.g., Bickle, 1978).
Park et al. (1984) and Park (1985) have suggested that over aperiod of about 50-100 Ma successive island arcs were formed in the Svecokarelian domain with progressively younger vo1canism towards the south. This model may be close to the truth, but its timing is not supported by radiometric data from vo1canic rocks. The relatively few data available so far (Helovuori, 1979; Aho, 1979; Patchett and Kouvo, 1986; Kähkönen et al., in press; this study) indicate two periods of vo1canic activity, 1910-1900 and 1890-1880 Ma. Both vo1canic pulses have occurred at least in the Pyhäsalmi and Tampere areas, and no vo1canism younger than 1880 Ma associated with the Svecokarelian orogeny has been detected even in the south Finnish archipelago. Thus there is no indication of measurable age differences between various vo1canic areas in the Svecofennian domain of Finland.
The radiometric data from the Raahe-Ladoga zone presented in this paper suggest that there were differences in the tectonie evolution in its various parts. As is demonstrated by the present results, at Vihanti the earliest intrusive rocks were emplaced 1900 Ma aga and aIl granitoid activity, including that of clearly posttectonic granites terminated about 1860 Ma ago, while the regional metamorphism culminated about 1880 Ma ago. Pegmatites and diabase dykes emplaced in fault zones cutting aIl phases of ductile deformation register titanite and zircon V-Pb ag es of about 1860 Ma. Thus all orogenic movements in the Vihanti area seem to have occurred within a time interval no longer than 40 Ma.
From Pyhäsalmi to Pielavesi and Rautalampi, tonalitic gneisses preceding aIl deformation and of probable mantle derivation have been dated at 1920 Ma. Early orogenic gabbros as weIl as syntectonic granitoids cutting the first de-
Geological Survey of Finland, Bulletin 343 27
formation phase yield ag es of about 1890-1880 Ma. As demonstrated by the Lammasaho granodiorite, tectonie activity in this area ceased about 1850 Ma ago.
However, in the Rantasalmi-Sulkava area, migmatitic rocks were still being generated 1830 Ma aga and the first posttectonic granitoids were emplaced about 1800 Ma ago. Thus, in this area, the tectonic processes lasted up to 50 Ma longer than elsewhere in the Raahe-Ladoga zone.
As is evident from Fig. 1. on p. 6, in the Vihanti area, which displays short-lived tectonic activity, the Raahe-Ladoga zone is surrounded by Svecofennian rocks , whereas the prolonged tectonism in the Savo Schist Belt occurred in an area where the Archaean craton beneath the Karelian formation was probably in direct contact with the accreting crust. The situation here is similar to that encountered in the W opmay orogene in Canada (Hoffman and Bowring, 1984) where, after a short culmination of the main orogenie activity, a second compressional phase resulted in further deformation and reactivation of the newly formed continental crust. It thus seems feasible to suggest that whatever the accretionary mechanism was at the margin of the Archaean continent, it led to a thickening of the newly forming material at the immediate zone of coIlision. This in turn resulted in higher temperatures in the piles of juvenile material giving rise to prolonged periods of heating.
Another factor worth consideration is that the Savo schist belt forms the hinge between the Raahe-Ladoga zone and the Svecofennian supracrustal formations running east-west through southern Finland and central Sweden (Ward, 1987). Thus the differences in isotope geology of the Joroinen-Sulkava area and the rest of the Raahe-Ladoga zone may be the result of a process that affected only southern Finland and central Sweden, leaving other parts of the continental crust generated during the Svecokarelian orogeny untouched.
Vo1canic rocks, early orogenic gabbros and syntectonic granitoids throughout Finland
28 Geological Survey of Finland , Bulletin 343
southwest of the Raahe-Ladoga zone register a relatively narrow range of ages from 1910 to 1870 Ma (e.g., Patchett et al., 1981; Patchett and Kouvo, 1986; Hopgood et al., 1983; Häkli et al., 1979; Welin et al., 1983). However , south of the line from Puruvesi to Pori (or about 62°N) ages of posttectonic granitoids range from 1820 to 1760 Ma (Vaasjoki, 1977; Simonen, 1982; Welin et al., 1983; Korsman et al., 1984, Nykänen , 1988); no posttectonic activity younger than 1850 Ma has been recorded north of the line . Similarly, only in the southern Svecofennides do migmatizing granites occur in the 1810-1840 Ma age range (e.g., Korsman et al., 1984; Hopgood et al., 1984; Huhma, 1986). Thus there is a distinct likelihood that a major tectonic boundary exist in southern Finland along the 62°N line.
Examining the concept of aseparate southern Finnish block still further , we note that the next significant addition to the crust of the Fennoscandian Shield occurred during the Gothian episode about 1750-1650 Ma aga (Claesson, 1987; Lindh, 1987) in central and southern Sweden .
The contact of this domain with the pre-existing continental crust trends almost N-S, and consequently the thrust from an oceanic plate should have come (in present day directions) from almost due west.
Our suggestion therefore is that the Svecofenni an crust, as it is exposed today, was generated by a collision of Proterozoic oceanic and Archaean continental plates between 1930 and 1850 Ma ago . This plate movement stagnated at about 1850 Ma but was, in the present-day southern Finland , immediately followed by eastward underplating of the newly formed continental crust, resulting in its migmatization around 1830-1810 Ma ago, the emplacement of the 1800-1780 Ma posttectonic granitoids and the formation of new continental crust in the Gothian area of Sweden from 1750 Ma onwards. Thus the present isotopic data from the RaaheLadoga zone could be interpreted as being indicative of several different plate tectonic processes closely related in time and space.
CONCLUSIONS
From studies of metapelites it is evident that, although detrital zircons tend to lose increasing amounts of radiogenic lead as the metamorphic temperature rises, even garnet-cordierite-biotite and garnet-cordierite-sillimanite grades of metamorphism do not result in the total resetting of zircon U-Pb systems. Our evidence from the contact of the Vaaraslahti intrusion and the Sulkava thermal dome suggest that temperatures in excess of 750°C are required to totally reset zircons.
The main geochronological groups along the Raahe-Ladoga zone may be summarized as follows: 1930-1910 Ma: volumetrically minor but spati
ally widely distributed granitoid rocks in the central part of the belt from Pyhäsalmi to Rautalampi;
1910-1900 Ma: intermediate-acidic lavas associated with base metal mineralization all along the belt;
1900-1880 Ma: early orgenic gabbros with associated nickel ores;
1890-1875 Ma: intrusion of syntectonic granitoids, hypersthene granites and plagioclase porphyrites/ ophitic gabbros all along the belt accompanied by the peak of regional metamorphism in the central and northwestern parts;
1880-1850 Ma: emplacement of posttectonic rocks in the northwestern and central parts of the belt;
1830-1810 Ma: peak of regional metamorphism and migmatization in the southeastern part of the belt;
1805-1795 Ma: emplacement of posttectonic rocks in the southeastern part of the belt. These results, together with other isotope data
from Finland, suggest that the new Svecofennian crust was rapidly generated between 1930 and 1850 Ma ago by the collision of a Proterozoic
Geological Survey of Finland, Bulletin 343 29
oceanic plate with an Archaean continent. Subsequent underplating in a W-E direction south of 62°N resulted in migmatization at about 1820 Ma and the emplacement of the ca. 1800 Ma posttectonic granites in southern Finland.
ACKNOWLEDGEMENTS
We are indebted to the technical staffs of the units for Isotope Geology, Mineralogy and Thematic Studies of the Department of Petrology of the Geological Survey of Finland for their valuable assistance in sampie collection, mineral separation, chemical purification and mass-spectrometer maintenance. Discussions and field excursions with Kalevi Korsman, Pentti Hölttä and Raimo Lahtinen were a great help at all stages
of this work. The assistance and hospitality received from Outokumpu OY and especially Eero Rauhamäki while MV was working in the Vihanti area is much appreciated . Constructive criticism by prof. Atso Vorrna, chief of the Department of Petrology and Drs. Olavi Kouvo and Hannu Huhma did much to improve the original manuscript. We also thank Mrs. Gillian Häkli for the linguistic correction of the manuscript.
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32 Geological Survey of Finland, Bulletin 343
Appendix 1. Description of analytical methods.
The minerals were separated from crushed rock sam pies (10-100 kg) using a shaking table, heavy liquids (methylene diodide, Clerici's solution) and magnetic procedures. The sizes of the analysed fractions varied from 1 to 10 mg, being typically about 5 mg. Some fractions were treated with the air abrasion technique (Krogh, 1982) in order to produce more concordant data. The fractions were finally purified by careful hand-picking and washed in an ultrasonic bath in 3 N HCl prior to dissolution.
Lead and uranium were dissolved and purified as described
Appendix 2. Locations of analysed sampies.
Sampie Location
A 780 Alpua, Vihanti A 781 Hirsikangas, Vihanti A 782 Korpi, Vihanti A 776 Lampinsaari, Vihanti A 898 Hirsikangas, Vihanti A 899 Käpylä, Vihanti A 938 Lampinsaari, Vihanti A 600 Lammasaho, Kiuruvesi A 83 Laajamäki, Pielavesi AI025 Yijäkönmäki, Pielavesi AI026 Yijäkönmäki, Pielavesi AI028 Sahinperä, Kiuruvesi AI075 Pyöreänsuonvuori, Rautalampi A 15 Vuotsinsuo, Joroinen AI022 Härkälä, Rantasalmi AI013 Viholanniemi, Joroinen AI099 Pirilä, Rantasalmi
by Krogh (1973). However, for titanites and monazites uranium was separated from iron by hexone extraction. The lead from so me of the galenas was purified using the anodic electrodeposition technique described by Gulson and Mizon (1979).
Linear regressions on the concordia diagrams were calculated according to the method of York (1969) assuming an accuracy of 1 ± 070 for the U/ Pb ratios and a 90% error correlation.
Map sheet Northing Easting
243408 7148.62 561.58 243405 7141.72 554.20 243402 7140.80 548.99 243405 7145.80 555.37 243405 7141.60 554.05 243404 7136.00 553.20 243405 7146.15 555.46 332311 7058 .80 492.60 331408 7028.70 481.00 331409 7031.55 488.13 331409 7031.41 488.07 332307 7042.95 482.03 322312 6945.40 495.68 323303 6888.29 544.39 323308 6872.80 562.80 323401 6890.16 540.50 323306 6881.20 555.80